Structure of Cotton Fiber:
Cotton, the seed hair of plants of the genus Gossypium, is the purest form of cellulose readily available in nature. It has many desirable fibre properties making it an important fibre for textile applications. Cotton is the most important of the raw materials for the textile
industry. The cotton fibre is a single biological cell with a multilayer structure The layers in the cell structure are, from the outside of the fiber to the inside, cuticle, primary wall, secondary wall, and lumen. These layers are different structurally and chemically. The primary and secondary walls have different degrees of crystallinity, as well as different molecular chain orientations. The cuticle, composed of wax, proteins, and pectins, is 2.5% of the fiber weight and is amorphous. The primary wall is 2.5% of the fiber weight, has a crystallinity index of 30%, and is composed of cellulose. The secondary wall is 91.5% of the fiber weight, has a crystallinity index of 70%, and is composed of cellulose. The lumen is composed of protoplasmic residues.
Cotton, the seed hair of plants of the genus Gossypium, is the purest form of cellulose readily available in nature. It has many desirable fibre properties making it an important fibre for textile applications. Cotton is the most important of the raw materials for the textile
industry. The cotton fibre is a single biological cell with a multilayer structure The layers in the cell structure are, from the outside of the fiber to the inside, cuticle, primary wall, secondary wall, and lumen. These layers are different structurally and chemically. The primary and secondary walls have different degrees of crystallinity, as well as different molecular chain orientations. The cuticle, composed of wax, proteins, and pectins, is 2.5% of the fiber weight and is amorphous. The primary wall is 2.5% of the fiber weight, has a crystallinity index of 30%, and is composed of cellulose. The secondary wall is 91.5% of the fiber weight, has a crystallinity index of 70%, and is composed of cellulose. The lumen is composed of protoplasmic residues.
Cotton fibres
have a fibrillar structure. The whole cotton fibre contains 88 to 96.5%
of cellulose, the rest are non-cellulosic polysaccharides constituting
up to 10% of the total fibre weight. The primary wall in mature fibres
is only 0.5-1 µm thick and contains about 50% of cellulose.
Non-cellulosic constituents consist of pectins, fats and waxes, proteins
and natural colorants. The secondary wall, containing about 92- 95%
cellulose, is built of concentric layers with alternatic shaped twists.
The layers consist of densely packed elementary fibrils, organized into
micro fibrils and macro fibrils. They are held together by strong
hydrogen bonds. The lumen forms the centre of the fibres. Cotton is
composed almost entirely of the polysaccharide cellulose. Cotton
cellulose consists of crystalline fibrils varying in complexity and
length and connected by less organized amorphous regions with an average
ratio of about two-thirds crystalline and one-third non-crystalline
material, depending on the method of determination.
The chemical composition
of cellulose is simple, consisting of anhydroglucose units joined by
β-1,4-glucosidic bonds to form linear polymeric chains. The chain
length, or degree of polymerisation (DP), of a cotton cellulose molecule
represents the number of anhydroglucose units connected together to
form the chain molecule. DP of cotton may be as high as 14 000, but it
can be easily reduced to 1000–2000 by different purification treatments
with alkali. The crystalline regions probably have a DP of 200 to 300.
Correspondingly, the molecular weight (MW) of cotton usually lies in the
range of 50,000–1,500,000 depending on the source of the cellulose. The
individual chains adhere to each other along their lengths by hydrogen
bonding and Van der Waals forces. The physical properties of the cotton
fibre as a textile material, as well as its chemical behaviour and
reactivity, are determined by arrangements of the cellulose molecules
with respect to each other and to the fibre axis.
Non Cellulosic Constituents of Cotton:
The primary wall is about 1 µm thick and comprises only about 1 % of the total thickness of cotton fibre. The major portion of the non-cellulosic constituents of cotton fibre is present in or near the primary wall. Non cellulosic impurities, such as fats, waxes, proteins, pectins, natural colorants, minerals and water-soluble compounds found to a large extent in the cellulose matrix of the primary wall and to a lesser extent in the secondary wall strongly limit the water absorbency and whiteness of the cotton fiber. Pectin is located mostly in the primary wall of the fibre.
It is composed of a high proportion of
D-galacturonic acid residues, joined together by α(1→4)-linkages. The
carboxylic acid groups of some of the galacturonic acid residues are
partly esterified with methanol. Pectic molecule can be called a
block-copolymer with alternating the esterified and the non-esterified
blocks. In the primary cell wall pectin is covalently linked to
cellulose or in other plants to hemicellulose, or that is strongly
hydrogen- bonded to other components. Pectin is like powerful biological
glue. The mostly water-insoluble pectin salts serve to bind the waxes
and proteins together to form the fiber`s protective barrier.
The general state of knowledge of the chemical composition of a mature cotton fiber is presented in Table
Table shows that non-cellulosic materials account for only a very small amount of the fiber weight. These materials are amorphous and are located in the cuticle and the lumen. The cuticle forms a protective layer to shield the cotton from environmental attacks and water penetration. Waxy materials are mainly responsible for the non-absorbent characteristics of raw cotton. Pectins may also have an influence, since 85% of the carboxyl groups in the pectins are methylated.
Row cotton fibres have to go through several chemical processes to obtain properties suitable for use. With scouring, non-cellulose substances (wax, pectin, proteins, hemicelluloses…) that surround the fibre cellulose core are removed, and as a result, fibres become hydrophilic and suitable for bleaching, dyeing and other processing.
By removing pectin, it is easier to remove all other non-cellulosic substances. The processes of bio-scouring that are in use today are based on the decomposition of pectin by the enzymes called pectinases.
 |
| Figure: Chemical structure of Cellulose. |
Non Cellulosic Constituents of Cotton:
The primary wall is about 1 µm thick and comprises only about 1 % of the total thickness of cotton fibre. The major portion of the non-cellulosic constituents of cotton fibre is present in or near the primary wall. Non cellulosic impurities, such as fats, waxes, proteins, pectins, natural colorants, minerals and water-soluble compounds found to a large extent in the cellulose matrix of the primary wall and to a lesser extent in the secondary wall strongly limit the water absorbency and whiteness of the cotton fiber. Pectin is located mostly in the primary wall of the fibre.
 |
| Figure: A schematic representation of cotton fibre showing its various layers. |
The general state of knowledge of the chemical composition of a mature cotton fiber is presented in Table
Composition
of a Fiber
|
Composition
of the Cuticle%
|
|||
Constituent
|
Typical%
|
Low%
|
High%
|
|
Cellulose
|
94.0
|
88.0
|
96.0
|
|
Protein
(N-6.25)
|
1.3
|
1.1
|
1.9
|
30.4
|
Pectic
substances
|
0.9
|
0.7
|
1.2
|
19.6
|
Wax
|
0.6
|
0.4
1
|
1.0
|
17.4
|
Mineral
matters
|
1.2
|
0.7
|
1.6
|
6.5
|
Maleic,
citric, and other organic acids
|
0.8
|
0.5
|
1.0
|
|
Total
sugars
|
0.3
|
|||
Cutin
|
8.7
|
|||
Table shows that non-cellulosic materials account for only a very small amount of the fiber weight. These materials are amorphous and are located in the cuticle and the lumen. The cuticle forms a protective layer to shield the cotton from environmental attacks and water penetration. Waxy materials are mainly responsible for the non-absorbent characteristics of raw cotton. Pectins may also have an influence, since 85% of the carboxyl groups in the pectins are methylated.
Row cotton fibres have to go through several chemical processes to obtain properties suitable for use. With scouring, non-cellulose substances (wax, pectin, proteins, hemicelluloses…) that surround the fibre cellulose core are removed, and as a result, fibres become hydrophilic and suitable for bleaching, dyeing and other processing.
By removing pectin, it is easier to remove all other non-cellulosic substances. The processes of bio-scouring that are in use today are based on the decomposition of pectin by the enzymes called pectinases.
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